Determine whether f is a function, an injection, a surjection Announcing the arrival of Valued Associate #679: Cesar Manara Planned maintenance scheduled April 17/18, 2019 at 00:00UTC (8:00pm US/Eastern)How to determine whether a sequence of functions converges uniformly or pointwise to a function?Is $z=x^2+y^2$ a bijection?Identify as an injection, surjection, bijection or non-functionDetermine whether each of these functions is a bijection from R to RWhat is the mistake in this proof?Determine Total/Partial Functions and Injection/Surjection/BijectionExplaining whether a function is injective/surjection ($fcolonBbb Nto P(Bbb N)$)Is this a surjection? (Elementary real analysis)Help on Surjection, Injection, and BijectionFunction One to One with coordinates

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Determine whether f is a function, an injection, a surjection



Announcing the arrival of Valued Associate #679: Cesar Manara
Planned maintenance scheduled April 17/18, 2019 at 00:00UTC (8:00pm US/Eastern)How to determine whether a sequence of functions converges uniformly or pointwise to a function?Is $z=x^2+y^2$ a bijection?Identify as an injection, surjection, bijection or non-functionDetermine whether each of these functions is a bijection from R to RWhat is the mistake in this proof?Determine Total/Partial Functions and Injection/Surjection/BijectionExplaining whether a function is injective/surjection ($fcolonBbb Nto P(Bbb N)$)Is this a surjection? (Elementary real analysis)Help on Surjection, Injection, and BijectionFunction One to One with coordinates










2












$begingroup$


Let $P= $p(x)$ is a polynomial of degree $n$, $n in Bbb Z^+cup0 $ with coefficients in $Bbb R $. Define $f : Prightarrow P$ where $f(p(x)) =p'(x)$, the derivative of $p(x)$.



Determine whether $f$ is a function, an injection, a surjection, a bijection.



Now I have the solutions, and I understand that it is a function because each polynomial has a unique derivative. And it is not an injection as the antiderivative of a given polynomial is not unique.



However, I do not understand the book's solution for determining whether it is a surjection, nor am I able to come up with one myself. In all honesty, I think I am having trouble understanding the mapping from P to P. The solution states that it is a surjection. Why is this so?










share|cite|improve this question









$endgroup$











  • $begingroup$
    This problem doesn't make sense. If $deg p(x)=n$, then $deg p'(x)=n-1$ and therefore, $p'(x)notin P$.
    $endgroup$
    – José Carlos Santos
    3 hours ago










  • $begingroup$
    Is $P$ the set of polynomials of degree $n$ exactly?
    $endgroup$
    – Bernard
    3 hours ago






  • 2




    $begingroup$
    I interpreted it to mean that it is the set of all polynomials.
    $endgroup$
    – Tony S.F.
    3 hours ago










  • $begingroup$
    I think he means the set of nonzero polynomials with coefficients in $mathbb R$.
    $endgroup$
    – Clayton
    3 hours ago






  • 1




    $begingroup$
    I read it more as the set of "all polynomials with degree that is a nonnegative integer." Though I do wonder of the need to specify that.
    $endgroup$
    – Eevee Trainer
    3 hours ago















2












$begingroup$


Let $P= $p(x)$ is a polynomial of degree $n$, $n in Bbb Z^+cup0 $ with coefficients in $Bbb R $. Define $f : Prightarrow P$ where $f(p(x)) =p'(x)$, the derivative of $p(x)$.



Determine whether $f$ is a function, an injection, a surjection, a bijection.



Now I have the solutions, and I understand that it is a function because each polynomial has a unique derivative. And it is not an injection as the antiderivative of a given polynomial is not unique.



However, I do not understand the book's solution for determining whether it is a surjection, nor am I able to come up with one myself. In all honesty, I think I am having trouble understanding the mapping from P to P. The solution states that it is a surjection. Why is this so?










share|cite|improve this question









$endgroup$











  • $begingroup$
    This problem doesn't make sense. If $deg p(x)=n$, then $deg p'(x)=n-1$ and therefore, $p'(x)notin P$.
    $endgroup$
    – José Carlos Santos
    3 hours ago










  • $begingroup$
    Is $P$ the set of polynomials of degree $n$ exactly?
    $endgroup$
    – Bernard
    3 hours ago






  • 2




    $begingroup$
    I interpreted it to mean that it is the set of all polynomials.
    $endgroup$
    – Tony S.F.
    3 hours ago










  • $begingroup$
    I think he means the set of nonzero polynomials with coefficients in $mathbb R$.
    $endgroup$
    – Clayton
    3 hours ago






  • 1




    $begingroup$
    I read it more as the set of "all polynomials with degree that is a nonnegative integer." Though I do wonder of the need to specify that.
    $endgroup$
    – Eevee Trainer
    3 hours ago













2












2








2


0



$begingroup$


Let $P= $p(x)$ is a polynomial of degree $n$, $n in Bbb Z^+cup0 $ with coefficients in $Bbb R $. Define $f : Prightarrow P$ where $f(p(x)) =p'(x)$, the derivative of $p(x)$.



Determine whether $f$ is a function, an injection, a surjection, a bijection.



Now I have the solutions, and I understand that it is a function because each polynomial has a unique derivative. And it is not an injection as the antiderivative of a given polynomial is not unique.



However, I do not understand the book's solution for determining whether it is a surjection, nor am I able to come up with one myself. In all honesty, I think I am having trouble understanding the mapping from P to P. The solution states that it is a surjection. Why is this so?










share|cite|improve this question









$endgroup$




Let $P= $p(x)$ is a polynomial of degree $n$, $n in Bbb Z^+cup0 $ with coefficients in $Bbb R $. Define $f : Prightarrow P$ where $f(p(x)) =p'(x)$, the derivative of $p(x)$.



Determine whether $f$ is a function, an injection, a surjection, a bijection.



Now I have the solutions, and I understand that it is a function because each polynomial has a unique derivative. And it is not an injection as the antiderivative of a given polynomial is not unique.



However, I do not understand the book's solution for determining whether it is a surjection, nor am I able to come up with one myself. In all honesty, I think I am having trouble understanding the mapping from P to P. The solution states that it is a surjection. Why is this so?







calculus functions derivatives elementary-set-theory






share|cite|improve this question













share|cite|improve this question











share|cite|improve this question




share|cite|improve this question










asked 3 hours ago









John ArgJohn Arg

496




496











  • $begingroup$
    This problem doesn't make sense. If $deg p(x)=n$, then $deg p'(x)=n-1$ and therefore, $p'(x)notin P$.
    $endgroup$
    – José Carlos Santos
    3 hours ago










  • $begingroup$
    Is $P$ the set of polynomials of degree $n$ exactly?
    $endgroup$
    – Bernard
    3 hours ago






  • 2




    $begingroup$
    I interpreted it to mean that it is the set of all polynomials.
    $endgroup$
    – Tony S.F.
    3 hours ago










  • $begingroup$
    I think he means the set of nonzero polynomials with coefficients in $mathbb R$.
    $endgroup$
    – Clayton
    3 hours ago






  • 1




    $begingroup$
    I read it more as the set of "all polynomials with degree that is a nonnegative integer." Though I do wonder of the need to specify that.
    $endgroup$
    – Eevee Trainer
    3 hours ago
















  • $begingroup$
    This problem doesn't make sense. If $deg p(x)=n$, then $deg p'(x)=n-1$ and therefore, $p'(x)notin P$.
    $endgroup$
    – José Carlos Santos
    3 hours ago










  • $begingroup$
    Is $P$ the set of polynomials of degree $n$ exactly?
    $endgroup$
    – Bernard
    3 hours ago






  • 2




    $begingroup$
    I interpreted it to mean that it is the set of all polynomials.
    $endgroup$
    – Tony S.F.
    3 hours ago










  • $begingroup$
    I think he means the set of nonzero polynomials with coefficients in $mathbb R$.
    $endgroup$
    – Clayton
    3 hours ago






  • 1




    $begingroup$
    I read it more as the set of "all polynomials with degree that is a nonnegative integer." Though I do wonder of the need to specify that.
    $endgroup$
    – Eevee Trainer
    3 hours ago















$begingroup$
This problem doesn't make sense. If $deg p(x)=n$, then $deg p'(x)=n-1$ and therefore, $p'(x)notin P$.
$endgroup$
– José Carlos Santos
3 hours ago




$begingroup$
This problem doesn't make sense. If $deg p(x)=n$, then $deg p'(x)=n-1$ and therefore, $p'(x)notin P$.
$endgroup$
– José Carlos Santos
3 hours ago












$begingroup$
Is $P$ the set of polynomials of degree $n$ exactly?
$endgroup$
– Bernard
3 hours ago




$begingroup$
Is $P$ the set of polynomials of degree $n$ exactly?
$endgroup$
– Bernard
3 hours ago




2




2




$begingroup$
I interpreted it to mean that it is the set of all polynomials.
$endgroup$
– Tony S.F.
3 hours ago




$begingroup$
I interpreted it to mean that it is the set of all polynomials.
$endgroup$
– Tony S.F.
3 hours ago












$begingroup$
I think he means the set of nonzero polynomials with coefficients in $mathbb R$.
$endgroup$
– Clayton
3 hours ago




$begingroup$
I think he means the set of nonzero polynomials with coefficients in $mathbb R$.
$endgroup$
– Clayton
3 hours ago




1




1




$begingroup$
I read it more as the set of "all polynomials with degree that is a nonnegative integer." Though I do wonder of the need to specify that.
$endgroup$
– Eevee Trainer
3 hours ago




$begingroup$
I read it more as the set of "all polynomials with degree that is a nonnegative integer." Though I do wonder of the need to specify that.
$endgroup$
– Eevee Trainer
3 hours ago










3 Answers
3






active

oldest

votes


















6












$begingroup$

To see that $f$ is a surjection we take an arbitrary element $y$ in $P$ and show that $exists xin P$ such that $f(x)=y$. This is what it means to be surjective; we cover the entire space with the image of $f$ on $P$.



Let $pin P$, i.e. $p$ is some polynomial $p(x)$. Then $p(x)$ has an antiderivative, $q(x) = int p(x)dx$. This antiderivative is a polynomial (easy to check), so it is in $P$. Then $f(q) = p$, and since $p$ was arbitrary, $f$ is therefore surjective.



Here is a more concrete analogy to help you understand what a surjection is.



Imagine you have two lists of names, one for adults and one for children. Imagine that someone says they have a way to assign names from the adult list to names in children list. Their way of assigning the names is surjective if every name is the children list is assigned at least one name in the adult list. This would mean that if you pick a name from the children list as random, there is at least one adult name corresponding to it.






share|cite|improve this answer











$endgroup$












  • $begingroup$
    This is exactly the solution presented in my book (albeit reworded) yet for some reason I am having trouble understanding it. It seems to be that I am having a problem with the first two lines. Perhaps I do not properly understand what surjection is?
    $endgroup$
    – John Arg
    3 hours ago


















1












$begingroup$

For any polynomial $p (x) $ there exists its integral $P (x) $, for which $p $ is a derivative: $$p (x)=P'(x)$$ and which itself is a real-coefficients polynomial, too $$P(x)in P$$ Hence each $p(x) in P$ is in the image of your function $f$. Then $f$ is surjective.






share|cite|improve this answer











$endgroup$




















    0












    $begingroup$

    Think about what the inverse mapping for $f$ would be if indeed it would be a surjection: it would take the derivatives to the original function. Phrased another way, it would take a function to its antiderivative, right?



    Well, we know that all polynomials have an antiderivative (which is itself a polynomial), and since the codomain of $f$ is basically the set of real polynomials, we have a pre-image for each polynomial in $P$ - its antiderivative. Thus, $f$ is surjective.






    share|cite|improve this answer









    $endgroup$












    • $begingroup$
      What do you mean by pre-image?
      $endgroup$
      – John Arg
      3 hours ago










    • $begingroup$
      You know how, say, $f(x)$ might be called the "image" for $x$? Same sort of deal: we would also say $x$ is the pre-image for $f(x)$. To use, arguably, more familiar terminology: inputs are to outputs, as pre-images are to images.
      $endgroup$
      – Eevee Trainer
      3 hours ago











    Your Answer








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    3 Answers
    3






    active

    oldest

    votes








    3 Answers
    3






    active

    oldest

    votes









    active

    oldest

    votes






    active

    oldest

    votes









    6












    $begingroup$

    To see that $f$ is a surjection we take an arbitrary element $y$ in $P$ and show that $exists xin P$ such that $f(x)=y$. This is what it means to be surjective; we cover the entire space with the image of $f$ on $P$.



    Let $pin P$, i.e. $p$ is some polynomial $p(x)$. Then $p(x)$ has an antiderivative, $q(x) = int p(x)dx$. This antiderivative is a polynomial (easy to check), so it is in $P$. Then $f(q) = p$, and since $p$ was arbitrary, $f$ is therefore surjective.



    Here is a more concrete analogy to help you understand what a surjection is.



    Imagine you have two lists of names, one for adults and one for children. Imagine that someone says they have a way to assign names from the adult list to names in children list. Their way of assigning the names is surjective if every name is the children list is assigned at least one name in the adult list. This would mean that if you pick a name from the children list as random, there is at least one adult name corresponding to it.






    share|cite|improve this answer











    $endgroup$












    • $begingroup$
      This is exactly the solution presented in my book (albeit reworded) yet for some reason I am having trouble understanding it. It seems to be that I am having a problem with the first two lines. Perhaps I do not properly understand what surjection is?
      $endgroup$
      – John Arg
      3 hours ago















    6












    $begingroup$

    To see that $f$ is a surjection we take an arbitrary element $y$ in $P$ and show that $exists xin P$ such that $f(x)=y$. This is what it means to be surjective; we cover the entire space with the image of $f$ on $P$.



    Let $pin P$, i.e. $p$ is some polynomial $p(x)$. Then $p(x)$ has an antiderivative, $q(x) = int p(x)dx$. This antiderivative is a polynomial (easy to check), so it is in $P$. Then $f(q) = p$, and since $p$ was arbitrary, $f$ is therefore surjective.



    Here is a more concrete analogy to help you understand what a surjection is.



    Imagine you have two lists of names, one for adults and one for children. Imagine that someone says they have a way to assign names from the adult list to names in children list. Their way of assigning the names is surjective if every name is the children list is assigned at least one name in the adult list. This would mean that if you pick a name from the children list as random, there is at least one adult name corresponding to it.






    share|cite|improve this answer











    $endgroup$












    • $begingroup$
      This is exactly the solution presented in my book (albeit reworded) yet for some reason I am having trouble understanding it. It seems to be that I am having a problem with the first two lines. Perhaps I do not properly understand what surjection is?
      $endgroup$
      – John Arg
      3 hours ago













    6












    6








    6





    $begingroup$

    To see that $f$ is a surjection we take an arbitrary element $y$ in $P$ and show that $exists xin P$ such that $f(x)=y$. This is what it means to be surjective; we cover the entire space with the image of $f$ on $P$.



    Let $pin P$, i.e. $p$ is some polynomial $p(x)$. Then $p(x)$ has an antiderivative, $q(x) = int p(x)dx$. This antiderivative is a polynomial (easy to check), so it is in $P$. Then $f(q) = p$, and since $p$ was arbitrary, $f$ is therefore surjective.



    Here is a more concrete analogy to help you understand what a surjection is.



    Imagine you have two lists of names, one for adults and one for children. Imagine that someone says they have a way to assign names from the adult list to names in children list. Their way of assigning the names is surjective if every name is the children list is assigned at least one name in the adult list. This would mean that if you pick a name from the children list as random, there is at least one adult name corresponding to it.






    share|cite|improve this answer











    $endgroup$



    To see that $f$ is a surjection we take an arbitrary element $y$ in $P$ and show that $exists xin P$ such that $f(x)=y$. This is what it means to be surjective; we cover the entire space with the image of $f$ on $P$.



    Let $pin P$, i.e. $p$ is some polynomial $p(x)$. Then $p(x)$ has an antiderivative, $q(x) = int p(x)dx$. This antiderivative is a polynomial (easy to check), so it is in $P$. Then $f(q) = p$, and since $p$ was arbitrary, $f$ is therefore surjective.



    Here is a more concrete analogy to help you understand what a surjection is.



    Imagine you have two lists of names, one for adults and one for children. Imagine that someone says they have a way to assign names from the adult list to names in children list. Their way of assigning the names is surjective if every name is the children list is assigned at least one name in the adult list. This would mean that if you pick a name from the children list as random, there is at least one adult name corresponding to it.







    share|cite|improve this answer














    share|cite|improve this answer



    share|cite|improve this answer








    edited 2 hours ago

























    answered 3 hours ago









    Tony S.F.Tony S.F.

    3,72421031




    3,72421031











    • $begingroup$
      This is exactly the solution presented in my book (albeit reworded) yet for some reason I am having trouble understanding it. It seems to be that I am having a problem with the first two lines. Perhaps I do not properly understand what surjection is?
      $endgroup$
      – John Arg
      3 hours ago
















    • $begingroup$
      This is exactly the solution presented in my book (albeit reworded) yet for some reason I am having trouble understanding it. It seems to be that I am having a problem with the first two lines. Perhaps I do not properly understand what surjection is?
      $endgroup$
      – John Arg
      3 hours ago















    $begingroup$
    This is exactly the solution presented in my book (albeit reworded) yet for some reason I am having trouble understanding it. It seems to be that I am having a problem with the first two lines. Perhaps I do not properly understand what surjection is?
    $endgroup$
    – John Arg
    3 hours ago




    $begingroup$
    This is exactly the solution presented in my book (albeit reworded) yet for some reason I am having trouble understanding it. It seems to be that I am having a problem with the first two lines. Perhaps I do not properly understand what surjection is?
    $endgroup$
    – John Arg
    3 hours ago











    1












    $begingroup$

    For any polynomial $p (x) $ there exists its integral $P (x) $, for which $p $ is a derivative: $$p (x)=P'(x)$$ and which itself is a real-coefficients polynomial, too $$P(x)in P$$ Hence each $p(x) in P$ is in the image of your function $f$. Then $f$ is surjective.






    share|cite|improve this answer











    $endgroup$

















      1












      $begingroup$

      For any polynomial $p (x) $ there exists its integral $P (x) $, for which $p $ is a derivative: $$p (x)=P'(x)$$ and which itself is a real-coefficients polynomial, too $$P(x)in P$$ Hence each $p(x) in P$ is in the image of your function $f$. Then $f$ is surjective.






      share|cite|improve this answer











      $endgroup$















        1












        1








        1





        $begingroup$

        For any polynomial $p (x) $ there exists its integral $P (x) $, for which $p $ is a derivative: $$p (x)=P'(x)$$ and which itself is a real-coefficients polynomial, too $$P(x)in P$$ Hence each $p(x) in P$ is in the image of your function $f$. Then $f$ is surjective.






        share|cite|improve this answer











        $endgroup$



        For any polynomial $p (x) $ there exists its integral $P (x) $, for which $p $ is a derivative: $$p (x)=P'(x)$$ and which itself is a real-coefficients polynomial, too $$P(x)in P$$ Hence each $p(x) in P$ is in the image of your function $f$. Then $f$ is surjective.







        share|cite|improve this answer














        share|cite|improve this answer



        share|cite|improve this answer








        edited 2 hours ago

























        answered 3 hours ago









        CiaPanCiaPan

        10.4k11248




        10.4k11248





















            0












            $begingroup$

            Think about what the inverse mapping for $f$ would be if indeed it would be a surjection: it would take the derivatives to the original function. Phrased another way, it would take a function to its antiderivative, right?



            Well, we know that all polynomials have an antiderivative (which is itself a polynomial), and since the codomain of $f$ is basically the set of real polynomials, we have a pre-image for each polynomial in $P$ - its antiderivative. Thus, $f$ is surjective.






            share|cite|improve this answer









            $endgroup$












            • $begingroup$
              What do you mean by pre-image?
              $endgroup$
              – John Arg
              3 hours ago










            • $begingroup$
              You know how, say, $f(x)$ might be called the "image" for $x$? Same sort of deal: we would also say $x$ is the pre-image for $f(x)$. To use, arguably, more familiar terminology: inputs are to outputs, as pre-images are to images.
              $endgroup$
              – Eevee Trainer
              3 hours ago















            0












            $begingroup$

            Think about what the inverse mapping for $f$ would be if indeed it would be a surjection: it would take the derivatives to the original function. Phrased another way, it would take a function to its antiderivative, right?



            Well, we know that all polynomials have an antiderivative (which is itself a polynomial), and since the codomain of $f$ is basically the set of real polynomials, we have a pre-image for each polynomial in $P$ - its antiderivative. Thus, $f$ is surjective.






            share|cite|improve this answer









            $endgroup$












            • $begingroup$
              What do you mean by pre-image?
              $endgroup$
              – John Arg
              3 hours ago










            • $begingroup$
              You know how, say, $f(x)$ might be called the "image" for $x$? Same sort of deal: we would also say $x$ is the pre-image for $f(x)$. To use, arguably, more familiar terminology: inputs are to outputs, as pre-images are to images.
              $endgroup$
              – Eevee Trainer
              3 hours ago













            0












            0








            0





            $begingroup$

            Think about what the inverse mapping for $f$ would be if indeed it would be a surjection: it would take the derivatives to the original function. Phrased another way, it would take a function to its antiderivative, right?



            Well, we know that all polynomials have an antiderivative (which is itself a polynomial), and since the codomain of $f$ is basically the set of real polynomials, we have a pre-image for each polynomial in $P$ - its antiderivative. Thus, $f$ is surjective.






            share|cite|improve this answer









            $endgroup$



            Think about what the inverse mapping for $f$ would be if indeed it would be a surjection: it would take the derivatives to the original function. Phrased another way, it would take a function to its antiderivative, right?



            Well, we know that all polynomials have an antiderivative (which is itself a polynomial), and since the codomain of $f$ is basically the set of real polynomials, we have a pre-image for each polynomial in $P$ - its antiderivative. Thus, $f$ is surjective.







            share|cite|improve this answer












            share|cite|improve this answer



            share|cite|improve this answer










            answered 3 hours ago









            Eevee TrainerEevee Trainer

            10.5k31842




            10.5k31842











            • $begingroup$
              What do you mean by pre-image?
              $endgroup$
              – John Arg
              3 hours ago










            • $begingroup$
              You know how, say, $f(x)$ might be called the "image" for $x$? Same sort of deal: we would also say $x$ is the pre-image for $f(x)$. To use, arguably, more familiar terminology: inputs are to outputs, as pre-images are to images.
              $endgroup$
              – Eevee Trainer
              3 hours ago
















            • $begingroup$
              What do you mean by pre-image?
              $endgroup$
              – John Arg
              3 hours ago










            • $begingroup$
              You know how, say, $f(x)$ might be called the "image" for $x$? Same sort of deal: we would also say $x$ is the pre-image for $f(x)$. To use, arguably, more familiar terminology: inputs are to outputs, as pre-images are to images.
              $endgroup$
              – Eevee Trainer
              3 hours ago















            $begingroup$
            What do you mean by pre-image?
            $endgroup$
            – John Arg
            3 hours ago




            $begingroup$
            What do you mean by pre-image?
            $endgroup$
            – John Arg
            3 hours ago












            $begingroup$
            You know how, say, $f(x)$ might be called the "image" for $x$? Same sort of deal: we would also say $x$ is the pre-image for $f(x)$. To use, arguably, more familiar terminology: inputs are to outputs, as pre-images are to images.
            $endgroup$
            – Eevee Trainer
            3 hours ago




            $begingroup$
            You know how, say, $f(x)$ might be called the "image" for $x$? Same sort of deal: we would also say $x$ is the pre-image for $f(x)$. To use, arguably, more familiar terminology: inputs are to outputs, as pre-images are to images.
            $endgroup$
            – Eevee Trainer
            3 hours ago

















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